TR2023018194A2 - NANOEMULSION BASED NANOCREEN FORMULATIONS CONTAINING SALICYLIC ACID, COCONUT OIL, VITAMIN C AND VITAMIN E IN COMBINED FORM - Google Patents

Abstract

This invention relates to nanoemulsion-based nanocream formulations containing salicylic acid to exfoliate the dead skin layer to provide an anti-aging effect, and coconut oil, vitamin C and vitamin E to provide cell renewal, nutrition and rejuvenation.

Description

DESCRIPTION NANOEMULSION BASED NANOCREAM FORMULATIONS CONTAINING SALICYLIC ACID, COCONUT OIL, VITAMIN C AND VITAMIN E IN COMBINED FORM Technical Field This invention relates to nanoemulsion based nanocream formulations containing salicylic acid to exfoliate the dead skin layer to provide anti-aging effect, and coconut oil, Vitamin C and Vitamin E in combination to provide cell renewal, nutrition and rejuvenation. State of the Art Aging is a basic biological process of living organisms. It means loss of skin function. Skin is one of the organs where the effects of aging are most clearly observed. Changes in the skin due to aging cause a decrease in the protective and balancing effect. Wound healing is also delayed in aged skin. This is due to the decrease in all metabolic processes, especially the cell proliferation that has to replace the lost tissue. Aged skin is more vulnerable and less resistant to external effects. This is due to the thinning of the skin and all its layers. Therefore, aging of the skin is not only a cosmetic problem but also a serious medical problem. Genetic factors and hormones are at the basis of intrinsic aging, which is called the natural aging process. In parallel with aging, there is a decrease in the barrier function of the skin, delayed wound healing, a decrease in thermoregulation ability, changes in the epidermis and dermis layers, a decrease in the number of melanocytes and fibroblasts, and functional losses in the sweat and oil glands. Over time, the amount of keratinocytes and fibroblasts accumulated in the skin and the rate of aging increase, the tissue hardens and wrinkles become more pronounced. As the skin’s ability to renew itself decreases, signs of aging such as wrinkles, dryness and age spots appear earlier on the skin. Intrinsic aging is characterized by dryness, fine lines and skin atrophy in areas exposed to and not exposed to the sun. The functional declines resulting from intrinsic aging are due to a decrease in the response between cells. Signs of intrinsic aging are fine wrinkles, transparent skin, fat loss, sagging skin, dry skin, insufficient sweating to cool the skin, and graying hair. Extrinsic aging is the most important factor in skin aging. It is defined as the premature aging of the skin that develops due to various factors independent of time. The rays coming from the sun are the most important environmental factor that plays a role in skin aging. Photoaging, more than 90% of the changes seen in the skin are due to environmental effects caused by chronic sun damage. These environmental effects accelerate, increase or prematurely start aging. Photoaging includes various lifestyle components such as exposure to sunlight, air pollution, cigarette smoke, repetitive muscle movements such as frowning or frowning, diet, sleeping position and general health status. Exposure to ultraviolet (UV) rays causes free radical formation and damages collagen tissue and elastin network. UV rays coming from the sun are divided into two depending on wavelength. UVB (290-320 nm) causes damage in the epidermis; while long wavelength UVA (320-400 nm) causes damage by passing into the dermis. Thus, cell renewal decreases and hyperpigmentation, dryness and wrinkles occur. Skin that has undergone photoaging appears wrinkled, saggy and hard, and pigmentation changes are observed. Internal and external aging are not independent of each other and increase each other's effects. For example, the effect of the external factor sun exposure can be reduced by the natural pigments produced in the skin. However, the decrease in the number of melanocytes as we age causes this protective effect to decrease. The number of melanocytes decreases by approximately 96% in old age. Skin aging depends on sun exposure and the degree of skin pigment. In skin exposed to sunlight for long periods, the melanocyte density rate is approximately twice as high as in unaffected skin. Photoaging is more common in fair-skinned individuals. Due to both intrinsic and extrinsic aging, the skin loses moisture and dries, and in addition, in advanced ages, connective tissue proteins in the skin decrease due to hormonal reasons. As a result of the sudden decrease in estrogen levels, the blood circulation and fibroblast activity of the skin decrease. Due to the decrease in collagen and elastin synthesis, dryness, itching, wrinkles, thinning and atrophy are observed in the skin. In addition, hyaluronic acid, sebaceous and eccrine gland secretions also decrease. In addition, sweat glands and subcutaneous blood flow also decrease. In cases where direct application of the active ingredient is not possible or there is a loss of effect, the active ingredient can be given in a carrier system in cosmetic products. Solutions, gels, emulsions, suspensions, powder preparations and aerosols are currently accepted as classical drug applications. In classical drug applications, frequent and repeated doses are used. The dose amount used for the active substance released to the diseased area or to the specified cell, tissue or organ to concentrate in the target area is important. Unwanted situations may occur when the dose used for the concentration of the active substance released into the system falls below the sufficient amount or exceeds the toxic level. It is not possible to provide these unwanted situations with conventional drugs and treatments. Topical formulations are preparations prepared with oily or oil-free plasters applied by spreading or rubbing on the skin, semi-solid at room temperature and softening at body temperature. Semi-solid formulations have a homogeneous appearance and soft consistency and are used in topical and systemic drug application, protection and hydration of the application area. Semi-solid formulations are considered to be thermo-reversible systems because their viscosity tends to decrease with increasing temperature. Among these groups of preparations, ointments, creams and gels have a wide range of applications. Ointments are generally oil-based formulations that form a coating layer on the skin. They prevent the body from losing heat and water. They have little spreading ability on the skin. Creams are semi-solid formulations that contain one or more dissolved or dispersed active ingredients and are mostly prepared as emulsions. They are formulated as water-in-oil or oil-in-water emulsions. While oil-in-water emulsions are suitable for water-soluble drugs, water-in-oil emulsions are suitable for oil-soluble drugs. Gels are systems consisting of organic macromolecules formulated as a colloidal dispersion of water, acetone, alcohol or propylene glycol with a gelling agent. They are semi-solid formulations that become liquid when exposed to heat, are oil-free and non-occlusive. Gels are easy to apply and wash off. Gels are transparent in single-phase systems and opaque in two-phase systems. Gels are basically divided into two types, organogel or hydrogel, depending on the nature of the liquid component they contain. In the selection of active ingredients for topical formulations, the physicochemical and biological properties of the active ingredient have an important effect on the performance and manufacturability of the product. Therefore, it is important to choose the right dosage form and appropriate drug concentration. In the selection of excipients for topical formulations, excipients that control drug release and cream viscosity, improve skin permeability, increase drug formulation stability, and prevent microbial growth and contamination are taken into consideration. Saturated and unsaturated fatty acids/fatty acid esters, hydrocarbons, and polyols are added to formulations as penetration enhancers or viscosity regulators. Viscosity enhancers have important effects on the retention of topical dosage forms on the skin and drug penetration. Emulsifiers assist the emulsification process during cream production and ensure physical stability of the product throughout its shelf life. When an emulsion formulation is developed, the type of emulsifier (anionic, cationic, or nonionic), its hydrophilic-lipophilic balance (HLB), log P, and concentration are essential elements. The choice and concentration of antioxidants are determined only by testing their effectiveness on the final product according to pharmacopoeial information. Buffering agents must be used to ensure chemical stability and physical compatibility of the formulation. As a result, the deficiencies in the old technique/method: J Conventional topical formulations are likely to cause irritation, poor penetration, immune response (allergy) and low plasma concentrations J Inability to provide personalized or lower dose treatment with current treatments, J Lack of combination of salicylic acid, coconut oil, vitamins C and E in current drugs or cosmetic products to prevent skin aging, and even the lack of nanoemulsion form and new generation fast penetrating and patient-compatible nanocream-based products, J Economic loss due to the lack of these 4 active ingredients in current treatment options, users having to take each one or their combinations separately, J Unsafe and toxicity risks caused by high doses of active ingredients or herbal active compounds in traditional topical products, J Risks of side effects seen in current dosage forms stability problems, J The lack of both nanotechnology and new generation semi-solid carrier systems in products that prevent skin aging, J Inability to provide better penetration of active ingredients into the skin with existing conventional drugs; inability to increase the effectiveness of the treatment, inability to shorten the duration of treatment and inability to increase the daily living standards of the patients can be listed. The changes that occur in the skin with the aging of the skin tissue, which means the loss of skin functions, cause the protective and balancing effect to decrease. In particular, topical anti-aging formulations containing vitamin E and vitamin C are at the forefront in this direction. Many fixed oils are also added to these formulations due to their anti-aging properties. Coconut oil is also at the forefront of these plants. It is a fixed oil that provides a rapid effect on wrinkles on the skin surface, softens and moisturizes dry skin. Salicylic Acid, one of the compounds that exfoliates the skin and removes skin blemishes by peeling it during the aging and renewal processes of the skin, is frequently used in these formulations. Overcoming the problems seen with classical topical formulations (decrease in penetration, inability to formulate incompatible substances together, dosing problems, negative patient compliance, etc.) with new generation drug delivery systems is an area that the pharmaceutical industry and scientific studies focus on today. With the use of these new generation delivery systems in topical formulations; Many innovations such as lower side effect formation, transportation of complex molecules, use of incompatible substances together, increasing the penetration rate and amount of drugs through the skin and skin renewal and/or rapid healing are offered as well as improving patient compliance. Description of the Invention In this description, nanoemulsion based nanocream formulations containing salicylic acid to peel the dead skin layer to provide anti-aging effect, coconut oil, Vitamin C and Vitamin E combined to provide cell renewal, nutrition and rejuvenation are described in a way that does not create any limiting effect. The structural and characteristic features of the invention and all its advantages will be understood more clearly thanks to the description written below and therefore the evaluation should be made by taking this description into consideration. The present invention; It is related to nanoemulsion based nanocream dosage form formulations that meet the above mentioned requirements, eliminate all disadvantages and bring some additional advantages. The primary purpose of the invention is to provide a faster and more effective treatment due to being in nanoemulsion based nanocream form. It is to create less irritation and less side effects with lower doses of active ingredients. Another purpose of the invention is to provide the effects of peeling the dead cell layer of the skin, stimulating new cell formation, accelerating new cell formation, tightening the skin and delaying cell aging together. Another purpose of the invention is to present a more effective and economically advantageous formulation with lower doses of active ingredients, which allows the person to use salicylic acid, coconut oil, vitamin C and vitamin E together for the first time in a nanotechnological formulation to prevent skin aging, and which is more effective and economically advantageous. In order to fulfill the above-mentioned purposes, this invention includes nanoemulsion-based nanocream formulations containing salicylic acid, coconut oil, vitamin C and vitamin E together in a combined form. By using nanotechnology, salicylic acid, coconut oil, vitamin C and vitamin E have been reduced to nano size, allowing the use of these drugs at lower doses. It is also designed as an innovative dosage form of nanoemulsion-based nanocream that will increase absorption and accelerate pharmacological effects, and it is aimed to increase the standard of living and comfort of users in preventing and regressing skin aging. Skin is a tissue with a strong immune system. With aging, the deterioration of the skin barrier and the increase in its sensitivity prepare the ground for skin infections. As age progresses, the density of Langerhans cells in the skin and the ability of these cells to migrate in response to cytokines decrease. T lymphocytes also decrease in number and become less responsive to specific antigens. While the ability of aging skin to produce some cytokines (such as interleukin-2) decreases, the ability to produce others (such as interleukin-4) increases. As a result of these changes, there is a decrease in the intensity of delayed hypersensitivity reactions, photocarcinogenesis, increased susceptibility to chronic skin infections and delays in wound healing. In addition, the immune system weakens as keratinocytes and cytokines in the skin structure decrease. As age progresses, the body's insulating function decreases as the number of sweat glands and the subcutaneous fat layer decreases. Thus, the tolerance of elderly individuals to cold decreases and the risk of hypothermia increases. Sensitivity in touch receptors decreases, and the sensation of heat, cold and pressure in the hands and feet also decreases. With aging, skin integrity deteriorates more easily as a result of increased water loss in the body and inadequate fluid intake from outside, and the risk of skin cancer increases as DNA repair slows down. Anti-aging also means delaying aging. It is an intervention used to delay skin aging and preserve aesthetic beauty. In other words, anti-aging care can also be said to be personal care that aims to improve physical and psychological health and aims for lifelong health. Youthful skin appearance can be preserved to some extent with less invasive options and the need for cosmetic surgery can be reduced. Application of skin protection and anti-aging treatment regimens should be started as early as possible and continued throughout life to counteract the effects of internal/external skin aging. In the treatment of wrinkles, increasing the thinned dermal collagen, regulating the epidermal cycle and preventing flaking of the stratum corneum come to the fore. The appearance of the stratum corneum can be improved by using a moisturizing product containing emollients to soften the skin surface and sunscreens to prevent further photodamage. It is recommended to use anti-aging products to increase wrinkles, damage and elasticity of the skin on the face. There are studies on the mechanisms that have an anti-aging effect on these products. Examples include using Vitamin E as an antioxidant to increase skin moisture; using alpha and beta hydroxy acids to reduce skin flaking, improve cell turnover and reduce fine wrinkles and mottled hyperpigmentation; and using salicylic acid chemical peels to increase exfoliation. The use of antioxidants, stem cell treatments, retinoids, hormone replacement therapies, dietary restrictions, antiprogeria strategies and protection against inflammation are also among the treatment approaches. Ascorbic acid is found in all layers of the skin, with a higher concentration in the epidermis. Since both photoaging and natural aging can reduce vitamin C levels in the epidermis and dermis, vitamin C deficiency causes skin aging. Therefore, external use of vitamin C is one of the interesting approaches to delay skin aging. Anti-aging activity has been proven in clinical applications of preparations containing vitamin C in concentrations of 5% to 15%. Vitamin C is easily oxidized in an aqueous environment by releasing its electrons. Thus, it functions as an antioxidant that eliminates reactive oxygen species (ROS) or free radicals. Antioxidants are necessary to neutralize ROS caused by UV exposure. Vitamin C is equally effective in protecting the skin against both UVB and UVA. UVA has been reported to cause skin aging and possible melanoma formation. UVB has been reported to cause sunburn, ROS, epidermal mutations, and skin cancers. To optimize protection from UV rays, it is important to use sunscreens together with a topical antioxidant. Vitamin C does not absorb UV rays, but it does provide a protective effect against UV rays by neutralizing free radicals. Skin keratinocytes have the capacity to accumulate high concentrations of vitamin C. Vitamin C alone provides photoprotection, but when used in combination with vitamin E, it provides better protection against UV rays. Vitamin E is a lipophilic antioxidant. Vitamin C and vitamin E together protect the hydrophilic and lipophilic parts of the cell, respectively. Vitamin C is a cofactor that plays a role in many enzymatic reactions in the body. Vitamin C supports collagen I and its expression. Vitamin C is known to help increase collagen in the skin when there is a collagen deficiency, and to directly or indirectly reduce the breakdown of collagen. Clinical evidence has been reported that topical use of vitamin C alleviates the symptoms of skin aging and is used in the treatment of hyperpigmentation. Studies have shown that vitamin C prevents collagen loss in the photoaging process and natural aging of the skin, thus reducing wrinkles and increasing skin elasticity. The dermal collagen enhancing and skin anti-aging effects of vitamin C have been reported to be more pronounced in patients with low vitamin C and collagen levels. On the other hand, there are limitations in its use due to the easy oxidation (photooxidation) of vitamin C and the difficulty of skin absorption due to being a hydrophilic compound. L-ascorbic acid is the most abundant antioxidant in the skin and is the biologically active form of vitamin C. The inclusion of vitamin C in emulsions, nanoparticles, liposomes and gels increases the stability of the products and skin permeability. It has been reported that emulsions prepared with nonionic surfactants significantly increase the stability of vitamin C by ensuring that it is retained in possible reverse micelles. Vitamin C is used in the oxidative cleaning process when exposed to factors that cause loss of elasticity, wrinkle formation, discoloration and skin dryness. products (hair dyes, soaps, detergents, bleaches); provides significant protection against skin changes that occur in direct injuries such as burns. When vitamin C is taken orally, its bioavailability in the skin is insufficient. For this reason, the use of vitamin C in dermatological products is widely preferred. The effectiveness of products containing vitamin C topically on wrinkled skin has been reported to be transmitted to the epidermis layer when plasma levels are low. When plasma levels are saturated with vitamin C, it has been reported that its amount in the skin does not increase with topical application. It is one of the most abundant fat-soluble antioxidants in human cells. The lipophilicity of vitamin E allows it to be easily applied to the skin and easily absorbed by the skin. For this reason, it continues to exist as an indispensable agent in the skin care industry. Today, it is found in the composition of many skin care products at concentrations of 2-20%. The most important effect of vitamin E is tissue regeneration. It has been reported that many formulations containing vitamin E increase the antioxidant protection of the skin barrier against skin aging, which is characterized by wrinkles and atypical pigmentation that occur as a result of exposure to intracellular and extracellular oxidative stress. The antioxidant activity of vitamin E is strongly dependent on the effects of biological agents such as vitamin C. This synergistic antioxidant activity makes vitamin E important in preventing skin aging and its use in skin treatments is becoming increasingly widespread. Topically applied vitamin E increases the hydration and water retention capacity of the stratum corneum. It also reduces acute skin responses such as erythema, edema, sunburn, cell deformation, lipid peroxidation, and immunosuppression after UV exposure. Vitamin E levels vary depending on the density of sebaceous glands in the skin. The highest vitamin E levels have been found in the lower layers of the stratum corneum, while the lowest levels have been reported in the upper layers. The concentration of vitamin E in the epidermis is twice that of the dermis. Alpha-tocopherol and tocopherol acetate are the most commonly used vitamin E derivatives in skin care products. While alpha-tocopherol is generally found in concentrations of 5% or less in cosmetic products, tocopherol acetate is generally used in lower concentrations. For example, it has been reported that products containing 0.2% o-tocopherol increase vitamin E levels in the stratum corneum and reduce lipid peroxidation in vivo, thus protecting the skin from the negative effects of oxidative stress and photoaging. Salicylic acid is a ß-hydroxy acid. It is a hydroxyl derivative of benzoic acid and consists of a carboxylic acid attached to the aromatic alcohol phenol. Salicylic acid has keratolytic and comedolytic properties. The use of salicylic acid on human skin causes thinning of the stratum corneum layer without any change in the thickness of the epidermis. Salicylic acid reduces the adhesion of corneocytes, causing these cells to loosen and subsequently detach. Salicylic acid, a lipophilic agent, removes intercellular lipids that are covalently bound to the stratum corneum surrounding the surface epithelial cells. This effect of salicylic acid on the epidermis is frequently used by many dermatologists in superficial chemical peels. Salicylic acid has been found to extract desmosomal proteins, including desmogleins. As a result of this effect, the cohesion of the epidermal cells is lost and they begin to flake off. Therefore, salicylic acid should now be considered a desmolytic agent rather than a keratolytic agent in terms of its mechanism of action. Because it is known to act by disrupting cellular connections rather than breaking or fragmenting intercellular keratin filaments. It is recommended to use sunscreens with a sun protection factor of 30-50 (SPF30- SPF50) in daily skin care products. Combination treatments containing salicylic acid (2-4%) and chemical peeling agents such as hydroquinone, alpha hydroxy acids, Jessner solution, trichloroacetic acid, retinoic acid, phenol, glycolic acid are frequently used in formulations that have a lightening effect on spots. Salicylic acid, which has a stronger effect as an alternative peeling, has clear advantages for renewing moderately photoaged facial skin. Its benefits include the removal of pigment spots, the reduction of surface roughness and the reduction of fine lines. In addition, salicylic acid has an excellent safety profile. Peeling stimulates collagen by causing the coagulation of membrane proteins and necrosis of the epidermis and dermis. In other words, peeling with salicylic acid is characterized by changes in the underlying dermal tissue without directly injuring the skin. It also has an anesthetic effect that is seen during peeling and increases the patient's ability to tolerate it. Medium-level chemical peels reach the epidermis and dermis layer, that is, the dermoepidermal junction. They are used to even out or lighten skin tone, reduce wrinkles and increase skin firmness through collagen synthesis. A chemical peel must exfoliate and penetrate the subpapillary dermis or deeper to achieve adequate collagen synthesis. Therefore, it is recommended to use peels containing salicylic acid. The properties and indications of salicylic acid vary depending on the concentration used. Salicylic acid is used in peeling treatments for acne vulgaris, melasma, post-inflammatory hyperpigmentation, freckles, lentigines, fine wrinkles, and photodamage (mild to moderate). In a study conducted on women with mild to moderate photodamage, salicylic acid was used as a peeling agent and improvement in surface roughness and pigmented lesions, as well as a reduction in fine lines, was reported. Salicylic acid also has anti-inflammatory properties. The anti-inflammatory effect of salicylic acid is reported to be between 0.5% and 5% (w/w). Coconut oil is a good skin moisturizer and softener. It is used in cosmetic and pharmaceutical formulations to prevent and protect the skin from drying out. Coconut oil is used in the cosmetic industry with its hair, skin and eyelash nourishing properties. Examples of cosmetic preparations in which it is used include sun oils, creams, make-up removers, lotions, lip balms and hair protectors. In cases where direct application of the active ingredient is not possible or there is a loss of effect, the active ingredient in cosmetic products can be given in a carrier system. Solutions, gels, emulsions, suspensions, powder preparations and aerosols are currently accepted as classical drug applications. Today, the application of antioxidants, peptides, growth factors and plant-based components in new drug carrier systems is increasing. Among these new generation drug delivery systems that can be used in cosmetic products are vesicular systems (liposomes, niosomes, transfersomes, ethosomes, novasomes), microparticles, nanoparticles (solid polymeric particles; microspheres, microcapsules, nanospheres, nanocapsules, nanocrystals), lipid nanoparticles (solid lipid nanoparticles and nanostructured lipid carriers), microemulsions and nanoemulsions. Studies on the use of plant-based components in cosmetic formulations with liposomes, phytosomes, transfersomes, nanoemulsions, nanoparticles, microemulsions, nanocrystals, cubosomes and microsponges are available in the literature. Especially nanoemulsions have been preferred in recent years in personal care products for continuously effective cosmetics and for delivering active ingredients to certain skin layers. It is seen that the droplet size in nanoemulsions can be reduced below 300 nm with new emulsifiers, thus providing an advantage in skin penetration. Due to their small size, nanoemulsions can pass through "rough" skin surfaces and thus increase the penetration of active ingredients. Using these systems, water loss from the skin can be prevented, and it is possible to maintain the stability of vitamins along with the repairing effect. Nanoemulsion is an important alternative for increasing the active ingredient delivery system and the duration of the drug in the target area in regeneration and targeting poorly soluble drugs, resulting in fewer side effects. Nanoemulsion consists of very fine, oil-in-water dispersions with small droplet diameters. It has a high surface area, which allows high-quality active ingredients, which are in high demand in cosmetics, to be better delivered to the skin. Nanoemulsion; They show little or no sediment due to the absence of creaming, sedimentation and flocculation, which makes their applications in cosmetology much more important than traditional emulsions. Nanoemulsions increase the effectiveness of the active ingredient or other molecules in the droplets to pass through the biological membranes in the skin. Tropical routes are used for the transportation of the active ingredient. When nanoemulsions are applied topically, they increase drug permeability compared to other topical treatments. Topical application offers advantages such as patient compliance and ease. In the cosmetic industry, topical products are widely applied in the form of moisturizers, anti-aging creams, and lotions. These nanocream formulations used in the transportation of nano-sized drugs have become quite popular in the cosmetic sector in recent years for their anti-aging effects. Various studies are ongoing on the anti-aging potential of nanoemulsions. This can help reduce fine lines and tighten the skin. In order to eliminate these problems, drug delivery systems (such as nano drug delivery systems) that reduce the dose of the active ingredient, extend the dosing interval, reduce and/or eliminate side and toxic effects, and deliver the active ingredient to the target area are becoming increasingly widespread. The effect of the raw materials or systems in the composition of cosmetic products is very important in the desired, expected or targeted properties of cosmetic products. In the context of personal cleaning and care; the use of advanced drug delivery systems is important in the success of cosmetic products where special performance is expected. These advanced drug delivery systems may have unique properties such as providing sustained effect, being able to deliver incompatible components in the same formula, increasing the stability of active ingredients, reducing the irritant properties of substances and increasing skin penetration. With the invention, a formulation has been developed that reduces unwanted changes that occur with aging of the skin (such as acne, spots, pigment differences); contributes to the skin's renewal process and keeps the skin younger and more vibrant; removes dead skin with a peeling effect on the skin, accelerates the formation of new skin cells and tightens the skin. For this reason, a new generation drug carrier system formulation has been developed that aims to prevent fine lines by creating an antioxidant effect with vitamin E and vitamin C; to clean dead skin cells by creating a peeling effect with salicylic acid; and to nourish the skin by moisturizing it with coconut oil. This invention relates to formulations that are likely to be used in the effective prevention and/or regression of skin aging by combining coconut oil, salicylic acid, vitamin E and vitamin C active ingredients in a new generation cream formulation in the form of a nanoemulsion. In this way, it is expected to penetrate the skin faster and thus to have a faster effect. In a preferred embodiment of the invention, the enanoemulsion formulation given in Table 1 and the nanocream formulation given in Table 2 contain at least one excipient specified below in accordance with the amounts: J At least one natural oil phase selected from the group comprising sunflower oil, coconut oil, sesame oil, oleic acid, cottonseed oil, olive oil, almond oil, canola oil, linseed oil, hazelnut oil, ethyl oleate or a combination thereof (more preferably sunflower oil, Table 1); At least one surfactant selected from the group comprising (e.g. J Compritol 888 ATO, Gelot 64, isopropyl myristate, sodium lauryl sulfate, 85), Lecithin, Gelucire® varieties, Caprylol 90, Lauroglycol 90, Labrasol®, Labrafil® varieties, Captex® varieties, Brij® 72, Capmul® varieties, Poloxamer 407 or a combination thereof (more preferably isopropyl myristate, Table 1); J Compritol 888 ATO, Gelot 64, isopropyl myristate, sodium lauryl sulfate, 85), at least one surfactant selected from the group comprising Lecithin, Gelucire® varieties, Caprylol 90, Lauroglycol 90, Labrasol®, Labrafil® varieties, Captex® varieties, Brij® 72, Capmul® varieties, Poloxamer 407 or a combination thereof (more preferably Gelucire 48/16, Table 1); at least one natural oil phase selected from the group comprising sunflower oil, coconut oil, sesame oil, oleic acid, cottonseed oil, olive oil, almond oil, canola oil, linseed oil, hazelnut oil, ethyl oleate or a combination thereof (more preferably coconut oil; Table 2); At least one natural oil phase selected from the group consisting of sunflower oil, coconut oil, alpha tocopherol (Vitamin E), sesame oil, oleic acid, cottonseed oil, olive oil, almond oil, canola oil, linseed oil, hazelnut oil, ethyl oleate or a combination thereof (more preferably alpha tocopherol (Vitamin E); At least one natural oil phase selected from the group consisting of sunflower oil, coconut oil, sesame oil, oleic acid, cottonseed oil, olive oil, almond oil, canola oil, linseed oil, hazelnut oil, ethyl oleate or a combination thereof (more preferably sunflower oil, Table 2); Compritol 888 ATO, Gelot 64, isopropyl myristate, sodium lauryl sulfate, such as 85), Lecithin, Gelucire® varieties, Caprylol 90, Lauroglycol 90, Labrasol®, Labrafil® varieties, Captex® varieties, Brij® 72, Capmul® varieties, Poloxamer 407 or a combination thereof (more preferably Compritol; at least one nanocream base constituent selected from the group comprising Lanette-O (cetostearyl alcohol), stearic acid, cetyl alcohol, stearyl alcohol or a combination thereof (more preferably Lanette-O, Table 2); at least one nanocream base constituent selected from the group comprising Lanette-O (cetostearyl alcohol), stearic acid, cetyl alcohol, stearyl alcohol or a combination thereof (more preferably stearyl alcohol, Table 2); At least one surfactant selected from the group comprising (e.g. Compritol 888 ATO, Gelot 64, isopropyl myristate, sodium lauryl sulfate, 85), Lecithin, Gelucire® varieties, Caprylol 90, Lauroglycol 90, Labrasol®, Labrafil® varieties, Captex® varieties, Brij® 72, Capmul® varieties, Poloxamer 407, oleic acid, ethyl oleate or a combination thereof (more preferably oleic acid, Table 2); At least one surfactant (more preferably PEG 40) selected from the group consisting of PEG 40 hydrogenated castor oil, ethyl oleate, oleic acid, Compritol 888 ATO, isopropyl myristate, sodium lauryl sulfate, Poloxamer 188, Tweens (20, 40, 60, Caprylol 90, Lauroglycol 90, Labrasol®, Labrafil® varieties, Captex® varieties, Brij® 72, Capmul® varieties, Poloxamer 407 or a combination thereof Table 1. Nanoemulsion Formulation Ingredient Name Available amount by weight (%) Vitamin E 0.5-10.0 Sunflower Oil 0.5-15.0 Vitamin C 0.5-20.0 Salicylic Acid 0.1-5.0 Isopropyl Myristate 0.5-10.0 Gelucire 48/16 0.5-10.0 Ultrapure Water 40.0-95.0 Ingredient Name Available amount by weight (%) Vitamin E 0.5-5.0 Sweet Almond Oil 0.5-10.0 Vitamin C 0.5-10.0 Salicylic Acid 0.5-5.0 Compritol 888 ATO 0.5-10.0 Lanetto-O 1.0-5.0 Stearyl Alkoil 1.0-5.0 Oleic Acid 0.5-10.0 PEG 40 Hydrogenated Castor Oil 0.5-10.0 Ultrapure Water 10.0-45.0 Nanoemulsion Formulation 25.0-75.0 The formulation developed in the preferred nanoemulsion application of the invention; coconut oil, vitamin E, sunflower oil, vitamin C, salicylic acid, isopropyl myristate, Gelucine® 48/16 and ultrapure water. In a preferred nanocream application of the invention, the developed formulation contains coconut oil, vitamin E, sweet almond oil, vitamin C, salicylic acid, Compritol 888 ATO, Lanetto-O, stearyl alcohol, oleic acid, PEG 40 hydrogenated castor oil, ultrapure water and the nanoemulsion formulation in Table 1. In an exemplary application of the invention, the developed nanoemulsion formulation is prepared by following the following process steps: The components constituting the oil phase are weighed into a 10mL glass vial, respectively, vitamin E, coconut oil, isopropyl myristate and sunflower oil are weighed on a balance with 1 mg sensitivity. The components forming the water phase are weighed into a 15mL glass vial using a balance with 1 mg sensitivity: salicylic acid, Gelucine® 48/16, vitamin C. Finally, ultrapure water is added to this phase. The water and oil phases are mixed separately in a multipoint mixer at 750 rpm for 30 minutes. Then, both phases are mixed in a heated magnetic mixer at 50 °C at 750 rpm for 10 minutes. After both phases are completely dissolved, the water phase is dropped onto the oil phase using a 22 G syringe for 2 minutes. It is then vortexed for 1 minute at 2000 rpm. The resulting rough emulsion is then sonicated using an ultrasonic probe at 60% power for 4 minutes. Nanoemulsions are obtained. In an exemplary application of the invention, the developed nanocream formulation is prepared by following the following steps: For the oil phase, coconut oil, vitamin E, and sweet almond oil are weighed in a 10mL beaker, respectively. Then, Lanette-O, stearyl alcohol, Compritol 888 ATO, and Acconon 0-44 are weighed on a scale with 1 mg sensitivity, respectively, and transferred to the beaker. For the water phase, salicylic acid and vitamin C are weighed in a 15mL glass vial, respectively, on a scale with 1 mg sensitivity. Tween 20 is then added. Finally, ultrapure water is weighed and added to the vial. The water and oil phases are mixed separately in a heated magnetic stirrer at 70 °C and 750 rpm for 5 minutes. After both phases are completely dissolved, the water phase is quickly transferred to the oil phase. The creams obtained are mixed with a glass rod until they reach room temperature. The nanoemulsion formulation is added to the cream formulation that has reached room temperature and mixed with a glass rod until a homogeneous mixture is formed to obtain nanocream formulations.TR TR TR TR TR TR TR TR TR TR TR TR TR

Claims (1)

1.